A method extracts all infinite ambiguity from an input finite-state transducer (FST). The input FST is factorized into a first factor and a second factor such that the first factor is finitely ambiguous, and the second factor retains all infinite ambiguity of the original FST. The first factor is defined so that it replaces every loop where the input symbol of every arc is an ε (i.e., epsilon, empty string) by a single arc with ε on the input side and a diacritic on the output side. The second factor is defined so that it maps every diacritic to one or more ε-loops.
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1. A method for extracting infinite ambiguity from an input finite-state transducer (EST) having a plurality of states and a plurality of arcs, comprising the steps of:
assigning to each state a set of epsilon loops and a unique diacritic representative of the set; each epsilon ioop in the set of epsilon ioops beginning and ending at a qorresponding state; said assigning step defining a first representation of the input EST and a second representation of the input EST;
building a first factor by inserting into the first representation of the input FST one auxiliary state for each state with a non-empty set of epsilon loops; wherein each auxiliary state has an arc that leads from the auxiliary state to the corresponding state and emits the corresponding unique diacritic when traversed;
removing from the first factor at least one epsilon loop without removing the arcs corresponding to the epsilon loop;
building a second factor by inserting into the second representation of the input FST two auxiliary arcs for each state with a non-empty set of epsilon loops; wherein the two auxiliary arcs are labeled with a diacritic, and wherein a first of the auxiliary arqs leads from an initial state to its corresponding state, and a second of the auxiliary arcs leads from its corresponding state to a final state; and
removing from the second factor all paths having partial epsilon loops; and
mapping each diacritic in the second factor to a corresponding set of epsilon loops, the first factor does not contain any infinite ambiguity while the second factor retains the infinite ambiguity of the input FST.
14. An apparatus for extracting infinite ambiguity from an input finite-state transducer (FST) having a plurality of states and a plurality of arcs, comprising:
means for assigning to each state a set of epsilon loops and a unique diacritic representative of the set; each epsilon loop in the set of epsilon loops beginning and ending at a corresponding state; said assigning means defining a first representation of the input FST and a second representation of the input FST;
means for building a first factor by inserting into the first representation of the input FST one auxiliary state for each state with a non-empty set of epsilon loops; wherein each auxiliary state has an arc that leads from the auxiliary state to the corresponding state and emits the corresponding unique diacritic when traversed;
means for removing from the first factor at least one epsilon loop without removing the arcs corresponding to the epsilon loop;
means for building a second factor by inserting into the second representation of the input FST two auxiliary arcs for each state with a non-empty set of epsilon loops; wherein the two auxiliary arcs are labeled with a diacritic, and wherein a first of the auxiliary arcs leads from an initial state to its corresponding state, and a second of the auxiliary arcs leads from its corresponding state to a final state; and
means for removing from the second factor all paths having partial epsilon loops; and
means for mapping each diacritic in the second factor to a corresponding set of epsilon loops, the first factor does not contain any infinite ambiauity while the second factor retains the infinite ambiguity of the input FST.
2. The method of
minimizing the first factor; and
minimizing the second factor.
3. The method of
concatenating at least one boundary symbol to the input FST; and
minimizing the input FST.
4. The method of
temporarily replace each arc of the epsilon loop with a diacritic to define a sequence of diacritics;
formulate a constraint that disallows the sequence of diacritics;
compose the constraint with the first factor; and
replace any remaining diacritics with an epsilon symbol.
5. The method of
6. The method of
7. The method of
8. The method of
9. The method of
10. The method of
11. The method of
12. The method of
13. The method of
15. The apparatus of
16. The apparatus of
17. The apparatus of
18. The apparatus of
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Priority is claimed from U.S. Provisional Application No. 60/194,493, filed Apr. 3, 2000 by the same inventor and assignee, which is hereby incorporated herein by reference.
Cross-reference is made to U.S. Patent Application Ser. Nos., which are all hereby incorporated herein by reference: Ser. No. 09/737,552, entitled “Method And Apparatus For Factoring Ambiguous Finite State Transducers”; Ser. No. 09/737,940, entitled “Method And Apparatus For Factoring Unambiguous Finite State Transducers”; Ser. No. 09/737,939, entitled “Method And Apparatus For Aligning Ambiguity In Finite State Transducers”; Ser. No. 09/737,758, entitled “Method And Apparatus For Factoring Finite State Transducers With Unknown Symbols”; Ser. No. 09/737,553, entitled “Method And Apparatus For Extracting Infinite Ambiguity When Factoring Finite State Transducers”; Ser. No. 09/737,857, entitled “Method And Apparatus For Reducing The Intermediate Alphabet Occurring Between Cascaded Finite State Transducers”; Ser. No. 09/737,757, entitled “Method And Apparatus For Extracting Short Runs Of Ambiguity From Finite State Transducers”.
1. Field of the Invention
The invention relates to finite-state language processing, and more particularly to methods for efficiently processing finite-state networks in language processing and other applications.
2. Description of Related Art
Many basic steps in language processing, ranging from tokenization to phonological and morphological analysis, disambiguation, spelling correction, and shallow parsing can be performed efficiently by means of finite-state transducers. Such transducers are generally compiled from regular expressions, a formal language for representing sets and relations. Although regular expressions and methods for compiling them into automata have been part of elementary computer science for decades, the application of finite-state transducers to natural-language processing has given rise to many extensions to the classical regular-expression calculus.
The term language is used herein in a general sense to refer to a set of strings of any kind. A string is a concatenation of zero or more symbols. In the examples set forth below, the symbols are, in general, single characters such as “a”, but user-defined multicharacter symbols such as “+Noun” are also possible. Multicharacter symbols are considered as atomic entities rather than as concatenations of single-character strings. A string that contains no symbols at all is called the empty string and the language that contains the empty string but no other strings is known as the empty string language. A language that contains no strings at all, not even the empty string, is called the empty language or null language. The language that contains every possible string of any length is called the universal language.
A set of ordered string pairs such as {<“a”, “bb”>, <“cd”, “ ”>} is called a relation. The first member of a pair is called the upper string, and the second member is called the lower string. A string-to-string relation is a mapping between two languages: the upper language and the lower language. They correspond to what is usually called the domain and the range of a relation. In this case, the upper language is {“a”, “cd”} and the lower language is {“bb”, “ ”}. A relation such as {<“a”, “a”>} in which every pair contains the same string twice is called an identity relation. If a relation pairs every string with a string that has the same length, the relation is an equal-length relation. Every identity relation is obviously an equal-length relation.
Finite-state automata are considered to be networks, or directed graphs that consist of states and labeled arcs. A network contains a single initial state, also called the start state, and any number of final states. In the figures presented herewith, states are represented as circles and arcs are represented as arrows. In the included diagrams, the start state is always the leftmost state and final states are marked by a double circle. Each state acts as the origin for zero or more arcs leading to some destination state. A sequence of arcs leading from the initial state to a final state is called a path. An arc may be labeled either by a single symbol such as “a” or a symbol pair such as “a:b”, where “a” designates the symbol on the upper side of the arc and “b” the symbol on the lower side. If all the arcs of a network are labeled by a single symbol, the network is called a simple automaton; if at least one label is a symbol pair the network is a transducer. Simple finite-state automata and transducers will not be treated as different types of mathematical objects herein. The framework set forth herein reflects closely the data structures in the Xerox implementation of finite-state networks.
A few simple examples illustrating some linguistic applications of finite-state networks are set forth below. The following sections will describe how such networks can be constructed.
Every path in a finite-state network encodes a string or an ordered pair of strings. The totality of paths in a network encodes a finite-state language or a finite-state relation. For example, the network illustrated in
Each state in
If the number of words in a language is finite, then the network that encodes it is acyclic; that is, no path in the network loops back onto itself. Such a network also provides a perfect hash function for the language, a function that assigns or maps each word to a unique number in the range from 0 to n−1, where n is the number of paths in the network.
The network illustrated in
In order to make the diagrams less cluttered, it is traditional to combine several arcs into a single multiply-labeled arc. For example, the arc from state 5 to state 6 abbreviates four arcs that have the same origin and destination but a different label: “+NN:0”, “+NNN:s”, “+VB:0”, “+VBZ:s”. In this example, “0” is the epsilon symbol, standing for the empty string. Another important convention illustrated in
The lower language of the lexical transducer in
Lexical transducers can be used for analysis or for generation. For example, to find the analyses for the word “leaves”, one needs to locate the paths that contain the symbols “1”, “e”, “a”, “v”, “e”, and “s” as such on the lower side of the arc label. The network in
0-1-1-e-2-a-3-v-4-e-5-+NNS:s-6,
0-1-1-e-2-a-3-v-4-e-5-+VBZ:s-6,
0-1-1-e-2-a-3-f:v-8-+NNS:e-9-0:s-6.
The result of the analysis is obtained by concatenating the symbols on the upper side of the paths: “leave+NNS”, “leave+VBZ”, and “leaf+NNS”.
The process of generating a surface form from a lemma, say “leave+VBD”, is the same as for analysis except that the input form is matched against the upper side arc labels and the output is produced from the opposite side of the successful path or paths. In the case at hand, there is only one matching path:
0-1-1-e-2-a:f-12-v:t-13-e:0-14-+VBD:0-6
This path maps “leave+VBD” to “left”, and vice versa.
The term “apply” is used herein to describe the process of finding the path or paths that match a given input and returning the output. As the example above shows, a transducer can be applied downward or upward. There is no privileged input side. In the implementation described here, transducers are inherently bi-directional.
Lexical transducers provide a very efficient method for morphological analysis and generation. A comprehensive analyzer for a language such as English, French, or German contains tens of thousands of states and hundreds of thousands of arcs, but it can be compressed to a relatively small size in the range of approximately 500 KB to 2 MB.
A relation may contain an infinite number of ordered pairs. One example of such a relation is the mapping from all lowercase strings to the corresponding uppercase strings. This relation contains an infinite number of pairs such as <“abc”, “ABC”>, <“xyzzy”, “XYZZY”>, and so on.
The lower/upper case relation may be thought of as the representation of a simple orthographic rule. In fact, all kinds of string-changing rules may be viewed in this way, that is, as infinite string-to-string relations. The networks that represent phonological rewrite rules, two-level rules, or the GEN relation in Optimality Theory are of course in general more complex than the simple transducer illustrated in FIG. 3.
A composition is an operation on two relations. If one relation contains the pair <x, y> and the other relation contains the pair <y, z>, the relation resulting from composing the two will contain the pair <x, z>. Composition brings together the “outside” components of the two pairs and eliminates the common one in the middle. For example, the composition of {<“leave+VBD”, “left”>} with the lower/upper case relation yields the relation {<“leave+VBD”, “LEFT”>}.
It is useful to have a general idea of how composition is carried out when string-to-string relations are represented by finite-state networks. Composition is advantageously thought of as a two-step procedure. First, the paths of the two networks that have a matching string in the middle are lined up and merged, as shown in FIG. 5. For the sake of perspicuity, the upper and lower symbols are shown explicitly on different sides of the arc except that zero (i.e., epsilon) is represented by a blank. The string “left” is then eliminated in the middle, yielding the transducer in
Once rule application is thought of as composition, it immediately can be seen that a rule can be applied to several words, or even infinitely many words at the same time if the words are represented by a finite-state network. Lexical transducers are typically created by composing a set of transducers for orthographic rules with a transducer encoding the source lexicon. Two rule transducers can also be composed with one another to yield a single transducer that gives the same result as the successive application of the original rules. This is a well-known fundamental insight in computational phonology.
The formal properties of finite-state automata are considered briefly below. All the networks presented in this background have the three important properties defined Table 1.
TABLE 1
Epsilon-free
There are no arcs labeled with the
epsilon (ε) symbol alone.
Deterministic
No state has more than one outgoing
arc with the same label.
Minimal
There is no other network with
exactly the same paths that has
fewer states.
If a network encodes a regular language and if it is epsilon-free, deterministic and minimal, the network is guaranteed to be the best encoding for that language in the sense that any other network for the same language has the same number of states and arcs and differs only with respect to the order of the arcs, which generally is irrelevant.
The situation is more complex in the case of regular relations. Even if a transducer is epsilon-free, deterministic, and minimal in the sense of Table 1, there may still be another network with fewer states and arcs for the same relation. If the network has arcs labeled with a symbol pair that contains an epsilon on one side, these one-sided epsilons could be distributed differently, or perhaps even eliminated, and this might reduce the size of the network. For example, the two networks in
For transducers, the intuitive notion of determinism makes sense only with respect to a given direction of application. But there are still two ways to think about determinism, as shown in Table 2.
TABLE 2
Functional
For any input there is at most one output.
Sequential
No state has more than one arc with the
same symbol on the input side.
Although the transducers in
If the relation itself is unambiguous in the relevant direction and if all the ambiguities in the transducer resolve themselves within some fixed number of steps, the transducer is called sequentiable. That is, an equivalent sequential transducer in the same direction can be constructed.
The sequentialization process combines the locally ambiguous paths into a single path that does not produce any output until the ambiguity has been resolved. In the case at hand, the ambiguous path contains just one arc. When a “b” is seen, the delayed “a” is produced as output and then the “b” itself in a one-sided epsilon transition. Otherwise, an “a” must follow, and in this case there is no delayed output. In effect, the local ambiguity is resolved with one symbol lookahead.
The network in
Even if a transducer is functional, it may well be unsequentiable if the resolution of a local ambiguity requires an unbounded amount of lookahead. For example, the simple-transducer illustrated in
This transducer reduces any sequence of “a”s that is preceded by a “b” to an epsilon or copies it to the output unchanged depending on whether the sequence of as is followed by a “c”. A sequential transducer would have to delay the decision until it reached the end of an arbitrarily long sequence of “a”s. It is clearly impossible for any finite-state device to accumulate an unbounded amount of delayed output.
However, in such cases it is always possible to split the functional but unsequentiable transducer into a bimachine, as will be described in further detail below. A bimachine for an unambiguous relation consists of two sequential transducers that are applied in a sequence. The first half of the bimachine processes the input from left-to-right; the second half of the bimachine processes the output of the first half from right-to-left. Although the application of a bimachine requires two passes, a bimachine is in general more efficient to apply than the original transducer because the two components of the bimachine are both sequential. There is no local ambiguity in either the left-to-right or the right-to-left half of the bimachine if the original transducer is unambiguous in the given direction of application.
The left-to-right half of the bimachine (
The bimachine in
In accordance with the invention, a process for factorizing a input finite-state transducer (FST) into two finite state transducers such that the first factor or FST is finitely ambiguous, and the second factor or FST retains the infinite ambiguity of the original FST. The first factor is defined so that every loop where the input symbol of every arc is an ε (i.e., epsilon, empty string) is replaced by to a single arc with ε on the input side and a diacritic on the output side. The second factor is defined so that it maps every diacritic to one or more ε-loops. Advantageously, the first factor does not contain any infinite ambiguity while the second factor retains the infinite ambiguity of the input FST.
In accordance with one aspect of the invention, there is provided a method, and apparatus therefor, for extracting infinite ambiguity from an input finite-state transducer (FST) having a plurality of states and a plurality of arcs. Initially, each state is assigned a set of epsilon loops and a unique diacritic representative of the set to define first representation of the input FST and a second representation of the input FST. Each epsilon loop in the set of epsilon loops begins and ends at a corresponding state.
A first factor is built by inserting into the first representation of the input FST one auxiliary state for each state with a non-empty set of epsilon loops, wherein each auxiliary state has an arc that leads from the auxiliary state to the corresponding state and emits the corresponding unique diacritic when traversed. Epsilon loops are removed from the first factor without removing the arcs corresponding to the epsilon loops.
A second factor is built by inserting into the second representation of the input FST two auxiliary arcs for each state with a non-empty set of epsilon loops, wherein the two auxiliary arcs are labeled with a diacritic, and wherein a first of the auxiliary arcs leads from an initial state to its corresponding state, and a second of the auxiliary arcs leads from its corresponding state to a final state. All paths having partial epsilon loops are removed from the second factor. In addition, each diacritic in the second factor is mapped to a corresponding set of epsilon loops.
These and other aspects of the invention will become apparent from the following description read in conjunction with the accompanying drawings wherein the same reference numerals have been applied to like parts and in which:
This disclosure is organized as follows. Some of the principal terms and conventions used in this description are set forth below. Following that, a simplified overview of the factorization processes (i.e., methods detaining processing instructions or operations) is presented in the context of other finite-state operations. Finally, the factorization processes are described in more detail, using more complex examples with more features that are relevant for factorization.
A. Terminology
Set forth below are definitions of some of the principal terms used in this specification. Other terms are explained at their first occurrence.
An input prefix of a state q of an FST (Finite State Transducer) or transducer is the part of an input string on a particular path that ranges from the initial state to the state q. An input prefix would be an accepted input string if q were a final state.
An input suffix of a state q of an FST is the part of an input string on a particular path that ranges from the state q to a final state. An input suffix would be an accepted input string if q were an initial state.
The input prefix set of a state q of an FST is the set of all input prefixes of q. The input prefix set of an arc a is the input prefix set of its source state.
The suffix set of a state q of an FST is the set of all input suffixes of q. The input suffix set of an arc a is the input suffix set of its destination state.
An ambiguity field is a maximal set of alternative subpaths that all accept the same sub-string in the same position of the same input string.
Ambiguity is a relation that maps an input string to more than one output strings, or alternatively, a set of arc sequences in an FST that encodes such a relation. Finite ambiguity maps an input string to a finite number of output strings; infinite ambiguity maps an input string to an infinite number of output strings. An FST is ambiguous if it contains at least one ambiguity of either type. It is finitely ambiguous if it contains only finite ambiguity, and infinitely ambiguous otherwise.
A diacritic is a special symbol. It is usually distinct from the input and output symbols of an unfactored FST, and serves a particular purpose as a placeholder typically in an intermediate processing step.
The unknown symbol (or any symbol), represented by “?”, denotes any symbol in the known alphabet and any unknown symbol. In a finite-state graph, it only denotes any unknown symbol.
B. Conventions
The conventions below are followed in this disclosure.
In finite-state graphs: Every FST has one initial state, labeled with number 0, and one or more final states marked by double circles. The initial state can also be final. All other state numbers and all arc numbers have no meaning for the FST but are just used to reference a state or an arc from within the text. An arc with n labels designates a set of n arcs with one label each that all have the same source and destination. In a symbol pair occurring as an arc label, the first symbol is the input and the second the output symbol. For example, in the symbol pair “a:b”, “a” is the input and “b” the output symbol. Simple (i.e. unpaired) symbols occurring as an arc label represent identity pairs. For example, “a” means “a:a”.
Use of brackets: Curly brackets (“{ }”) include a set of objects of the same type, e.g., {100, 102, 106} denotes a set of arcs that are referred to by their numbers. Ceiling brackets (“┌ ┐”) include an ordered set of arcs that constitute a path or subpaths through an FST, e.g., ┌100, 101, 102, 103┐ is a path consisting of the four named arcs. Angle brackets (“< >”) include an n-tuple of objects of possibly different types, e.g., <qs, qd, σin, σout> denotes a quadruple of two states and two symbols.
C. Factoring Ambiguous Finite State Transducers
This initial Section C of the specification, which refers to
C.1 Summary of Factoring Ambiguous Finite State Transducers
An ambiguous finite-state transducer (“FST”) is an object that accepts a set of possible input strings, and for every accepted input string, outputs one or more output strings by following different alternative paths from an initial state to a final state. In addition, there may be a number of other paths that are followed from the initial state up to a certain point where they fail. Following these latter failing paths is necessary (up until the point they fail) to determine whether they can be successful, but that represents an inefficiency (loss of time).
A method is proposed herein for factoring an ambiguous FST with failing paths into two factors which are Finite State Transducers (FSTs). Factor 1 is functional (i.e. unambiguous) but still has failing paths, while factor 2 retains the ambiguity of the original FST but is fail-safe when applied to the output of factor 1. The application of factor 2 never leads to a state that does not provide a transition for the next input symbol, i.e., factor 2 has no failing paths.
Subsequently, factor 1 can in turn be factorized into a left-sequential and a right-sequential FST that jointly represent a bimachine. See Marcel Paul Schützenberger, “A remark on finite transducers,” Information and Control, 4:185-187 (1961) and Emmanuel Roche and Yves Schabes, eds., Finite-State Language Processing, MIT Press (Cambridge, Mass., U.S.A 1997), 1-66. As used herein, the terms “left-sequential,” “left-deterministic,” “right-deterministic,” and the like are shorthand terms intended to mean “left-to-right-sequential,” “left-to-right-deterministic,” and “right-to-left-deterministic,” respectively, as would be known to a practitioner of ordinary skill in the art. These two sequential FSTs plus factor 2 of the first factorization together represent a trimachine. Any input string is processed by this trimachine, first deterministically from left to right, then deterministically from right to left, and finally ambiguously but without failing paths from left to right. Alternatively, the trimachine can be converted into a modified bimachine by composing the right-sequential with the ambiguous FST. The FST that results from this composition is ambiguous but without failing paths. Any input string is processed by the modified bimachine, first deterministically from left to right and then ambiguously but without failing paths from right to left.
The proposed factorization offers the following advantages: First, with a trimachine or a modified bimachine input strings can be processed faster than with an ordinary FST because no time is spent on failing paths. Second, the functional and the ambiguous part of an FST can be studied and manipulated separately which can be useful with FSTs representing rule systems that generate ambiguous results such as parsers or part-of-speech taggers.
Although FSTs are inherently bidirectional, they are often intended to be used in a given direction. The proposed factorization is performed with respect to the direction of application. The two sides (or tapes or levels) of an FST are referred to herein as input side and output side.
C.2 Overview of Factoring Ambiguous Finite State Transducers
This section gives a simplified overview of the factorization process that is explained in more detail at a later stage, and situates it in a context of other finite-state operations. A simple example is used.
As mentioned above, an ambiguous FST returns for every accepted input string one or more output strings by following different alternative paths from the initial state to a final state. In addition there may be a number of other paths that are followed from the initial state up to a certain point where they fail. For example, the FST in
Even for input strings that are not accepted there may be more than one failing path. Following all of them is necessary but represents an inefficiency (loss of time). For example, the input string “caba” is not accepted but requires following five failing paths, namely ┌100, 102, 105┐, ┌100, 102, 106┐, ┌100, 103, 107┐, ┌100, 104, 108┐, and ┌101, 104, 109┐.
The factorization process set forth herein builds two FSTs, a first factor and a second factor, from an ambiguous FST such that in the first factor, a set of alternative arcs is collapsed into one arc that is labeled with a diacritic on the output side, and in the second factor, this diacritic is mapped to a set of alternative output symbols.
The FST in
All substrings that are accepted outside an ambiguity field are mapped by the first factor to their final output (FIG. 14). This output is then accepted by the second factor without any further modification, by means of a loop on the initial state. In the above example this loop consists of the arc 300 that is actually a set of four looping arcs with one symbol each (FIG. 15).
The first factor is functional (i.e. unambiguous) but not sequential, i.e., even for accepted input strings it can contain failing paths (FIG. 14). For the input string “cabca” it has one successful path formed by the ordered arc set ┌201, 203, 205, 207, 209┐, and one failing path formed by the ordered arc set ┌200, 202, 204┐. The second factor is ambiguous (it retains the ambiguity of the original FST) but it is fail-safe for all strings in the output language of the first factor, i.e., an arc is never traversed in vain (FIG. 15).
Since the first factor is functional (FIG. 14), it can be factored into a left-sequential FST (
Finally, the trimachine (
The following Sections C.3-C.5 explain the factorization of ambiguous FSTs in more detail, and refer to a flow chart set forth in FIG. 19 and finite state transducers and automata in
C.3 Starting Point of Factorization
The factorization of the ambiguous FST in
In general, an FST can contain arcs where neither of these two premises (i.e., neither equivalent nor disjoint prefixes and suffixes) is true. In the above example this concerns the two arcs 703 and 704 (FIG. 20). They have identical input symbols “b” and identical input prefix sets {ana} but their input suffix sets, {ε, bca, bcb, bcc} and {bca, bcb, bcc } respectively, are neither equivalent nor disjoint. These two arcs are only partially alternative arcs, and it is not decidable whether to collapse them. To make this question always decidable, the original FST is pre-processed in such a way that the sets of input prefixes and input suffixes of all arcs become either equivalent or disjoint, without altering the relation that is described by the FST.
C.4 Factorization Pre-processing
The first steps of the pre-processing consists of concatenating the FST (
The second step of the pre-processing consists of a left-unfolding of the minimal FST (step 1114), based on its left-deterministic input finite state automaton (input FSA). The input FSA, which is illustrated in
Every state q of the left-unfolded FST corresponds to one state qm of the minimal FST and to one state qL of the left-deterministic input FSA. The relation between these states can be expressed by:
∀qεQ,qmεQm,qLεQL:
qm=m(q)
qL=L(q)
In the left-unfolded FST of the above example (FIG. 23), every state is labeled with a triple of state numbers <q, qm, qL>. For example, states 9 and 10 are labeled with the triples <9, 8, 5> and <10, 8, 2> respectively which means that they are both copies of state 8 of the minimal FST but correspond to different states of the left-deterministic input FSA, namely to the states 5 and 2 respectively.
Every state q of the left-unfolded FST (
The left-unfolded FST describes the same relation as the minimal FST.
The third step of the pre-processing consists of a right-unfolding of the previously left-unfolded FST (step 1116), based on its right-deterministic input FSA (calculated in step 1115). The right-deterministic input FSA and the right-unfolded FST are illustrated in
Every state q of the fully (i.e. left and right) unfolded FST (
∀qεQ,qmεQm, qL,εQL,qRεQR:
qm=m(q)
qL=L(q)
qR=R(q)
In the fully unfolded FST of the above example (illustrated in FIG. 25), every state is labeled with a quadruple of state numbers <q, qm, qL, qR>. For example, the states 11, 12, 13, and 14 are labeled with the quadruples <11, 8, 5, 2>, <12, 8, 5, 4>, <13, 8, 2, 4>, and <14, 8, 2, 2> which means that they are all copies of state 8 of the minimal FST (qm=8).
Every state q of the unfolded FST has the same input prefix set as the corresponding state qL of the left-deterministic input FSA and the same input suffix set as the corresponding state qR of the right-deterministic input FSA:
∀qεQ:
PREin(q)=PREin(L(q))
SUFin(q)=SUFin(R(q))
Consequently, two states of the unfolded FST have equal input prefix sets if they correspond to the same state qL, and equal input suffix sets if they correspond to the same state qR:
∀qi,qjεQ:
PREin(ql)=PREin(qj)L(qi)=L(qj)
SUFin(qi)=SUFin(qj)R(qi)=R(qj)
The input prefix and input suffix sets of the states of the unfolded FST are either identical or disjoint. Partial overlaps cannot occur.
Equivalent states of the unfolded FST are different copies of the same state of the minimal FST. This means, two states are equivalent if and only if they correspond to the same state qm of the minimal FST:
ql≡qj:
Every arc a of the fully unfolded FST can be described by a quadruple:
a=<s,d,σin,σout> with a εA,s,dεQ,σinεΣin,σoutεΣout
where s and d are the source and destination state, and σin and σout the input and output symbol of the arc a respectively. For example, the arc 1302 of the fully unfolded FST (
Alternative arcs represent alternative transductions of the same input symbol in the same position of an input string. Two arcs are alternative arcs with respect to each other if and only if they have the same input symbol and equal input prefix and suffix sets. The input prefix set of an arc is the input prefix set of its source state, and the input suffix set of an arc is the input suffix set of its destination state:
Equivalent arcs are different copies of the same arc of the minimal FST. Two arcs are equivalent if they have the same input and output symbol, and equivalent source and destination states:
Two equivalent arcs are also alternative with respect to each other but not vice versa.
The fully unfolded FST describes the same relation as the minimal FST. The previously undecidable question whether two arcs are alternative to each other and should be collapsed, is decidable for the fully unfolded FST.
C.5 Factors
After the pre-processing, preliminary factors can be built as shown in
Arc sets can have different locations with respect to ambiguity fields. Singleton sets (e.g., {1300} or {1302}) and sets where all arcs are equivalent with respect to each other (there is no such example illustrated in
Begin(A):∀ai,ajεA:st≡sj;
an arc set A is at the end of an ambiguity field if and only if the destination states of all arcs in the set are equivalent (e.g., {1317, 1320} and {1314, 1329}):
End(A):∀ai,ajεA:di≡dj;
and an arc set A is at an ambiguity fork, i.e., at a position where two or more ambiguity fields with a common (overlapping) beginning separate from each other, if and only if there is an arc ai, in this set and an arc ak in another set so that both arcs have the same input symbol, equivalent source states, and disjoint input suffix sets. This means that the corresponding state qm=m(si)=m(sk) of the minimal FST can be left via either arc, ai, or ak, but one of them is on a failing path, and therefore should not be taken (e.g., {1317, 1320} and {1318, 1321}):
Fork(A):∃aiεA,ak∉A:(σiin=σkin)^(si≡sk)^(SUFin(di)≠SUFin(dk)).
Every arc of the unfolded FST (
All arcs of an arc set that is inside an ambiguity field (step 1118) are copied to both preliminary factors with their original location (regarding their source and destination) but with modified labels (FIGS. 26-27). They are copied to the first preliminary factor (step 1124) with their common original input symbol σin and a common intermediate symbol σmid (as output), and to the second factor (step 1126) with this intermediate symbol σmid (as input) and their different original output symbols σmid. This causes the copy of the arc set in the first factor to perform a functional transduction and to collapse into one single arc when the first factor is minimized. The intermediate symbol of an arc set can be a diacritic that is unique within the whole FST, i.e., that is not used for any other arc set.
If there is concern about the size of the factors and their alphabets, diacritics should be used sparingly. In this case, the choice of a common intermediate symbol σmid for a set of alternative arcs depends on the location of the arc set with respect to an ambiguity field, as follows.
At the beginning of an ambiguity field, the common intermediate symbol σmid is a diacritic that must be unique within the whole FST. For example, the arc set {1312, 1313} (
At a fork position that does no coincide with the beginning of an ambiguity field, the common intermediate symbol a σmid is a diacritic that needs to be unique only among all arc sets that have the same input symbol and the same input prefix set. This diacritic can be re-used with other forks. For example, the arc set {1317, 1320} gets the diacritic ψ0, i.e., the arcs change their labels from {c:x, c:y} to {c:φ0, c:φ0} in the first factor and to {φ0:x, φ0:y} in the second factor.
In all other positions inside an ambiguity field, the common intermediate symbol σmid equals the common input symbol σin of all arcs in a set. For example, the arc set {1315, 1316} gets the intermediate symbol “b”, i.e., the arcs change their labels from {b:x, b:y} to {b, b} in the first factor and keep their labels in the second factor.
At the end of an ambiguity field, one of the above rules for intermediate symbols σmid is applied. In addition, an arc labeled with the empty string ε is inserted in the second factor from the destination state of every arc in the set to the initial state of the FST, which causes the ambiguity field to end at the initial (final) state after minimization.
The final factors shown in
D. Improvements to Bimachine Factorization
This section describes three improvements to the bimachine factorization process proposed by Roche and Schabes (1997), which is cited above.
Any functional (i.e., unambiguous) FST can be converted into a bimachine (see Schützenberger, 1961, cited above), which in turn can be factored into a left-sequential FST and a right-sequential FST that together are equivalent to the bimachine. Processes for those transformations were proposed by Roche and Schabes. Such transformed bimachines have the advantage of having higher processing speed by virtue of their sequentiality (i.e., no backtracking is necessary), despite the fact that one FST has been replaced with two. Moreover, left and right context dependencies are made explicit, which allows them to be handled separately. However, the Roche and Schabes method can create a large number of additional symbols, and furthermore, the method is not applicable to FSTs that contain transitions for the unknown symbol. The methods set forth herein solve those problems. They create symbols more sparingly and avoid a direct factorization of the unknown symbol.
Although FSTs are inherently bidirectional, they are often intended to be used in a given direction. The original Roche and Schabes factorization method and the improvements set forth below are performed with respect to the direction of application. In this document, the two sides of an FST are referred to as the input side and the output side.
A bimachine can be described by a quintuple, as follows:
B=<Σin,Σout,A1,A2,δ>.
It consists of an input alphabet Σin, an output alphabet Σout, a left-deterministic automaton A1, a right-deterministic automaton A2, and an emission function δ that can be represented by a matrix, which is shown in Table 3. One way to obtain the output is that the two automata process the same input sequence, left-to-right and right-to-left respectively, and generate a sequence of states (i.e., state numbers) each. Based on these two state sequences and on the original input sequence, the emission function matrix shown in Table 3 generates the output sequence.
As discussed above, methods are known for converting a functional FST into a bimachine, and for factoring a bimachine into two sequential FSTs. The Roche and Schabes method is described with reference to
This functional FST T shown in
TABLE 3
##STR00001##
To obtain an output, e.g., for the input sequence “xaxaya”, A1 processes this sequence as shown in Table 4, from left to right (LR), and generates the state sequence 0121200 consisting of the numbers of all states on the path that match the input (FIG. 31). Then, A2 processes the same input as shown in Table 4, from right to left (RL), and generates the state sequence 000100 (written from right to left). The input sequence and the two state sequences constitute a sequence of triples, <0,x,0>, <1,a,0>, <2,x,0>, <1,a,1>, <2,y,0>, <0,a,0>, where every triple <q1,σin,q2> consists of state q1 of A1, an input symbol σin, and a state q2 of A2. Every triple can be mapped to an output symbol σout by means of the emission function matrix (no matter in which direction and order). For example, the triple <1,a,0> is mapped to the output symbol “a” because the corresponding matrix element (row 1, column 0) contains among others a transition where the symbol “a” is mapped to itself. The triple <1,a,1> is mapped to “b”. The whole sequence of triples is mapped to “xaxbya” (FIGS. 31-32), as shown in Table 4.
TABLE 4
A1:
xaxaya
##STR00002##
012120[0]
A2:
xaxaya
##STR00003##
[0]000100
δ:
(0,x,0)(1,a,0)(2,x,0)(1,a,1)(2,y,0)(0,a,0)
##STR00004##
xaxbya
This process of producing an output is equivalent to first applying a left-sequential FST T1 and then a right-sequential FST T2. In this case, T1 maps the input to a sequence of intermediate symbols, and T2 maps this intermediate sequence to an output sequence. An intermediate symbol σmid corresponds to a pair (q1,σin) consisting of a state q1 of T1 and an input symbol σin.
A factorization matrix {circumflex over (δ)} is set forth in Table 5; it results from an emission function matrix that is enhanced with intermediate symbols σmid. Here, every transition has the form σin:σmid:σout. Every intermediate symbol consists of the respective input symbol plus an index that is equal to the number of the corresponding state q1 of A1 (and equal to the row number).
TABLE 5
##STR00005##
The left-sequential FST T1 1814 (
The right-sequential FST T2 1816 (
The input sequence “xaxaya”, e.g., is mapped (LR) by T1 1814 to “x0a1x2a1y2a0”, which in turn is mapped (RL) by T2 1816 to “xaxbya” (FIGS. 33-34). The known factorization approach works essentially as set forth above. It does not explicitly create a factorization matrix, but the resulting left-sequential and right-sequential FSTs are the same (FIGS. 33-34).
The above example of a functional FST (
The known method proposes to remove all arcs with ε on the input side, and to concatenate their output symbols with the output of adjacent non-epsilon arcs. For example, the path ┌1903, 1906, 1909, 1910┐ labeled with ┌ε:v, ε:v, ε:z, ε:v┐ (
Note that the original (
The above process for converting a functional FST into a bimachine, for factoring this bimachine into a left-sequential and a right-sequential FST, and for eliminating arcs with ε on the input side can cause several problems. First problem: the factorization process can create a relatively large number of additional arcs and symbols (
Some solutions to these problems are set forth below.
D.1 Reduction of the Intermediate Alphabet
A solution to the first problem described above is as follows, and is considered with reference to the flow chart set forth in FIG. 39. In the factorization matrix {circumflex over (δ)} (Table 5), every intermediate symbol has an index corresponding to the row number. This is not necessary. Rows that are equal in the emission matrix δ (Table 3) can use the same index in the factorization matrix {circumflex over (δ)} (Table 5). Equal rows do not need to be distinguished.
Initially, an emission matrix is determined (step 2110). After the emission matrix is determined, the emission matrix is split into a set of emission sub-matrices, one for every input symbol (step 2112). Table 6 shows the emission sub-matrix δa for the input symbol “a”, for the example discussed above with reference to
TABLE 6
##STR00006##
With these intermediate symbols shown in Table 6, a factorization sub-matrix {circumflex over (δ)}a is created for the input symbol “a”, as described above while referring to Tables 3 and 5 (step 2114). The resulting factorization sub-matrix {circumflex over (δ)}a for the input symbol “a” is set forth in Table 7. Note that only one additional symbol is introduced for the input symbol “a”.
TABLE 7
##STR00007##
In the same way, we separately build an emission sub-matrix δ for every other input symbol (step 2112), define row indices and intermediate symbols, and create a factorization sub-matrix {circumflex over (δ)} (step 2114). Tables 8 and 9 illustrate this process for the input symbol “x”. No additional symbols are introduced, neither for “x” nor for any of the remaining input symbols. In these cases, all rows are equal and can use the index 0, that by convention is not expressed.
TABLE 8
##STR00008##
TABLE 9
##STR00009##
Based on the factorization sub-matrices of all input symbols, a left-sequential FST and a right-sequential FST are constructed (step 2116) using the above process discussed while referring to
D.2 Ambiguity Alignment
A solution to the second problem described above is as follows, considered with reference to the flow chart of FIG. 42.
Instead of removing all arcs labeled with ε (epsilon, the empty string), those arcs are replaced with a diacritic that can be factored like an ordinary symbol. This creates two problems that the following approach has to resolve.
Firstly, ε represents a non-determinism. Therefore, the left-sequential FST and right-sequential FST built by factorization should not contain ε on the input side. This issue will be addressed at the end of this section.
Second, the number of ε-arcs preceding or following a set A of alternative arcs that match the same input symbol after the same input prefix, can be different for different arcs in A. In the example of
First, the original (or input) FST T is concatenated on the right side with a boundary symbol, # (step 2410), and is minimized (
Then, a left-deterninistic input FSA is created by extracting the input side of the minimal FST, and determinizing it from left to right (
Finally, an FST with aligned ambiguity can be created (step 2416). It will be referred to as an aligned FST. Every state of the minimal FST is copied to the (new) aligned FST as many times as it occurs in different state sets of the input FSA (
TABLE 10
Alternative Sub-Paths In
AL
Tm
Ta
0┌a┐1
{0┌a:x┐1, 0┌a:y┐2}
{0┌a:x┐1, 0┌a:y┐2}
0┌c┐3
{0┌ε:y, c:z┐5, 0┌ε:v, ε:v, c:z┐7}
{0┌ω:δ, ω:y, ω:z┐4,
0┌ω:v, ω:v, c:z┐5}
1┌c┐2
{1┌ε:v, c:z┐8, 2┌c:z┐5}
{1┌ω:v, c:z┐6, 2┌ω:δ, c:z┐3}
2┌b┐4
{5┌b:y┐8}
{3┌b:y┐7}
2┌#┐5
{8┌#┐9}
{6┌#┐8}
3┌b┐4
{5┌b:y┐8}
{4┌b:y┐7}
3┌#┐5
{7┌ε:v, #┐9}
{5┌ω:v, #┐8}
4┌#┐5
{8┌#┐9}
{7┌#┐8}
For each arc in the left-deterministic FSA, a corresponding sub-path in the minimal FST is identified (step 2420). For the copying of arcs from the minimal to the aligned FST, alternative sub-paths of the minimal FST are recorded in Table 10 (step 2422). Column 1 of Table 10 lists all arcs of the input FST with their source and destination states. For example, “0┌c┐3” means that the input FSA contains an arc labeled with “c” that leads from state 0 to state 3. Column 2 shows the corresponding set of sub-paths in the minimal FST consisting each of one or more arcs and a source and destination state. For example, {┌ε:y,c:z┐5, 0┌ε:v,ε:v,c:z┐7} means that the arc 0┌c┐3 of the input FST corresponds to two sub-paths in the minimal FST, namely one sub-path labeled with ┌ε:y,c:z┐ e that leads from state 0 to state 5, and another sub-paths labeled with ┌ε:v,ε:v,c:z┐ that leads from state 0 to state 7. Note that every sub-path contains only one non-ε-arc. This arc is always the last one, and can be preceded by ε-arcs.
Subsequently, all sub-paths within one set are aligned (to equal length) by pre-pending arcs labeled with “ω:ε” (column 3 of Table 10) (step 2424). All previously existing ε are replaced on the input side by the diacritic ω. For example, the above mentioned set becomes {0┌ω:ε,ω:y,c:z┐4, 0┌ω:v,ω:v,c:z┐5} where all sub-paths are now three arcs long. Here, the source and destination states q (in the aligned FST;
All aligned sub-paths are inserted into the aligned FST as described in Table 10 (step 2426). Additional states are inserted where required (
The aligned FST is functional and can be factorized by the previously described process (step 2432), including improvements described herein (FIGS. 48-49). The diacritic ω is factored like an ordinary symbol. In the resulting left-sequential FST T1 (only), ω is replaced on the input side by the diacritic δ that represents a “deterministic empty string.”
In an arbitrary FST, ε represents a non-determinism whenever a state has an outgoing arc for a particular input symbol σin and an ε-arc. Both arcs must be traversed because the ε-arc (or a chain of ε-arcs) can lead to a state that has an outgoing arc for σin. This non-deterministic situation cannot occur with δ in a left-sequential FST T1resulting from the factorization of an aligned FST. In T1, every state has either an arc for a particular σin, or a δ-arc (or a chain of δ-arcs) that leads to a state that has an arc for σin, or none of either. Due to the structure of an aligned FST, no state of T1 can have both arcs. This means that every state of T1 is sequential.
For example, the state 0 of the original FST in this example (
When T1 is applied to an input string, a δ-arc must not be traversed if another (non-δ-) arc can be traversed. A δ-arc must be traversed if no other (non-δ-) arc can be traversed. This behavior is deterministic, and T1 is, therefore, sequential. If T1 is applied, e.g., to the input sequence “cb”, it produces the intermediate sequence “ωω1cb” as follows: The δ-arcs 2701 and 2703 must be traversed because at that point there are no arcs that would accept the input symbol “c”. Then, the arcs 2705 and 2708 are traversed and match “c” and “b”, respectively. The δ-arc 2707 must not be traversed because the state 6 has an outgoing arc (namely 2708) that matches “b”. When the right-sequential FST T2 is applied to an intermediate sequence, the diacritics ω and ω1 (o are treated like ordinary symbols, and ε as the ordinary empty string (FIGS. 48-49).
D.3 Factorization of the Unknown Symbol
The following method describes a solution to the third problem described above, and is considered with reference to the flow chart set forth in FIG. 50. However, it should be noted that the solution to the first problem described above has a side effect of solving many instances of this problem as well.
The unknown symbol, “?”,of the first example (
When the left-sequential FST T1 is applied, e.g., to the input sequence “ixixiy”, it produces, from left to right, the intermediate sequence “ixiλ1xiλ1y” on the path ┌3100, 3103, 3107, 3108, 3103, 3107, 3108, 3102┐. T2 maps the latter sequence, from right to left, to the output “ixixay” on the path ┌3204, 3206, 3210, 3202, 3203, 3211, 3202, 3200┐ (FIGS. 52-53).
E. Complete Factorization of Arbitrary Finite State Transducers
This section describes different enhancements to factorization processes, such as the process described in Section C above, to make them more generally applicable and more efficient.
E.1 Extraction of Infinite Ambiguity
This section describes. This means that all infinite ambiguity is extracted and separately described. The process is meant to be applied before the previously proposed method set forth in Section C of factoring finitely ambiguous FSTs, which method is not applicable to FSTs with infinite ambiguity. However, it can also be used in other contexts. In particular, it will be shown how different factorization processes can be applied together.
Infinite ambiguity is always described by “ε-loops,” i.e., loops where the input symbol of every arc is an ε (epsilon, empty string). In the proposed factorization, every ε-loop in the first factor is replaced by a single arc with ε on the input side and a diacritic on the output side. This means that the first factor does not contain any infinite ambiguity. Instead of (perhaps infinitely) traversing an ε-loop, a diacritic is emitted. The second factor maps every diacritic to one or more ε-loops. This means that the second factor retains the infinite ambiguity of the original FST.
The diacritic {circumflex over (ε)} denotes the (ordinary) empty string, like ε (FIG. 56). Both have the same effect when the FST is applied to an input sequence or when it is involved in standard finite-state operations. However, {circumflex over (ε)} should be preserved in minimization and determinisation, whereas ε is removed. The reason to preserve {circumflex over (ε)} here and in the following example is that otherwise, the second factor would become larger (FIGS. 56 and 63).
The above example, illustrated in
To extract all infinite ambiguity from an arbitrary FST, the method proceeds as follows, and as shown in the flow charts of
Then, each state qi is assigned the set Ei of ε-loops that all start (and end) at qi (step 3714), and a diacritic ξi that is considered as equivalent to the set Ei (
Both factors, Ξ1 and Ξ2, are built from this form of the FST (
In the first factor, for every state qi with a non-empty set Ei, an auxiliary state qiaux and an auxiliary arc aiaux that leads from qiaux to qi are inserted (
To remove all ε-loops without removing their arcs, the ε on the input side of every arc of all ε-loops is temporarily replaced by a diacritic ζj (
Cζ=(?*((ζ0ζ1ζ2)∪(ζ3ζ2)∪(ζ1ζ2ζ0)∪(ζ2ζ0ζ1)∪(ζ2ζ3))?*)
When the constraint Cζ is composed onto the input side of Ξ1′ (step 3732), all ε-loops disappear:
However, instances of the ζj-arcs remain if they are also part of another path than these ε-loops. Finally, every ζj in Ξ1″ is replaced again with an ε (step 3734), the boundary symbol, “#”, is replaced by ε (step 3736), and the first factor is minimized (step 3738) (FIG. 64). The final form of the first factor will be referred to as Ξ1. Note that an initially introduced diacritic ξi can disappear from Ξ1 because none of the incoming arcs of a particular state have been redirected.
The second factor is built (step 3720) from the same modified form of the original FST as the first factor (FIG. 61). The details of building the second factor Ξ2 (step 3720) are set forth in FIG. 60. The second factor must map any diacritic ξi to the corresponding set Ei of ε-loops. For every state qi with a non-empty set Ei, two auxiliary arcs, both labeled with the diacritic ξi, are created (
This composition removes all undesired paths. In this example, the constraint is (FIG. 63):
The resulting Ξ2″ maps any sequence of two identical diacritics ξiξi to itself, and inserts the corresponding set Ei of ε-loops in between (step 3750). The second occurrence of every ξi is actually unwanted. It is removed by the composition:
The resulting Ξ2′″ maps any single diacritic ξi to the corresponding set Ei. The {circumflex over (ε)} denotes the (ordinary) empty string, like ε. Both have the same effect when the FST is applied to an input sequence or when it is involved in standard finite-state operations. However, {circumflex over (ε)} should be preserved in minimization and determinisation, whereas ε is removed. The reason for preserving {circumflex over (ε)} is to prevent the final form of the second factor from otherwise becoming larger. If the size is of no concern, ε can be used instead.
The final form of the second factor, Ξ2, must accept any sequence of output symbols of the first factor, Ξ1, i.e., any sequence in Σ1out*. Within such a sequence, every diacritic ξi must be mapped to the corresponding set Ei of ε-loops, and every other symbol must remain unchanged. Ξ2 is obtained by (step 3752):
This operation has the side effect that all diacritics ξi that initially have been introduced by the process but have disappeared later from Ξ1 are also removed from Ξ2. Finally, Ξ2 is minimized (
Jointly in a cascade, the two factors, Ξ1 and Ξ2, describe the same relation and perform the same mapping as the original FST (see FIGS. 64-65). When Ξ1 and Ξ2 are composed with each other, the original FST is obtained.
The size increase of the second factor, compared to the original FST, is not necessarily a concern. The second factor could be an intermediate result that is further processed. For example, the ε-loops in the second factor could be removed, or modified, or preserved, and the second factor could then be composed again with the first factor or with a part of it that results from another factorization (step 3721). It is discussed below in Section E.4 how different factorization processes can be applied together.
E.2 Post-reduction of the Intermediate Alphabet
The following section describes a method, while referring to the flow chart in
In one embodiment, the method can be used with any other two FSTs that operate in a cascade (step 1410). With longer cascades, it can be applied pair-wise to all FSTs, preferably starting from the last pair.
First, the process is applied to the second factor, or in the general case, to the second FST of a pair.
The first step consists of constituting (i.e., identifying) non-overlapping equivalence classes of diacritics in the input alphabet (i.e., symbols) of the second factor (step 4412). Two symbols, e.g., ψi and ψj, are considered equivalent if for every arc with ψi on the input side, there is another arc with ψj on the input side and vice versa, so that both arcs have the same source and destination state and the same output symbol. From the above example (FIG. 68), we obtain the non-overlapping equivalence classes {ψ0}, {ψ1, ψ2}, and {ψ3, ψ4}. Here, ψ0 constitutes a class on its own because it first co-occurs with ψ1 and ψ2 in the arc set {4500, 4501, 4502}, and later with ψ3 and ψ4 in the arc set {4520, 4521, 4522}.
When the equivalence classes are constituted, all occurrences of all diacritics are replaced by the representative of their class which can be, e.g., the first member of the class (step 4414). This replacement must be performed on both the output side of the first factor and the input side of the second factor (step 4416). The resulting first factor and the second factor can then be minimized (step 4418).
The process reduces the set of intermediate diacritics a posteriori, i.e., it cannot prevent their creation in the first place. The process can be applied not only to diacritics but to every symbol in the intermediate alphabet of two factors.
E.3 Extraction of Short Ambiguity
The following section describes a method for extracting “short” ambiguity. The method is described with reference to the flow chart of FIG. 72. Generally, the method factorizes any arbitrary FST into two FSTs. The first factor, T1, contains most of the original FST, and the second factor, T2, contains those parts of the ambiguity of the original FST that are one arc long, regardless of whether this is finite or infinite ambiguity.
Based on these sets, the first factor, i.e. Γ1, is created from the original FST. The output symbol of every arc is replaced by the diacritic γi of the set that the arc belongs to (step 4914). For example, the output symbols of the arcs 5000 and 5001 are replaced by γ0. The resulting Γ1 is minimized (
The second factor (FIG. 75), i.e. Γ2, is directly created from the above symbol sets (step 4918). Γ2 has only a single state and a set of arcs that loop on this state. The arcs either map a diacritic γi to any of the output symbols that correspond to γi, or they map any of the ordinary output symbols of Γ1 to itself.
Although the method presented in this section cannot extract ambiguity that is longer than one arc (and that can be extracted by other factorization processes), it has the advantage of creating intermediate diacritics more sparingly, i.e., it prevents a priori the creation of some redundant diacritics. The method can be used as a preprocessing step for those other factorization processes.
E.4 Applications
This final section summarizes different factorizations and related processes, and describes how they can be applied together to any arbitrary FST.
Each of the following processes factorizes an FST into two FSTs that are referred to as a first factor and a second factor. When applied to an input sequence, the two factors operate in a cascade. The first factor maps the input to intermediate sequences which in turn are mapped by the second factor to final output sequences:
(A) Extraction of infinite ambiguity. Factorization of an arbitrary FST such that the first factor, Ξ1, is at most finitely ambiguous, and the second, Ξ2, retains all infinite ambiguity of the original FST.
(B) Extraction of “short” ambiguity. Factorization of an arbitrary FST such that the second factor, Γ2, contains all ambiguity that is one arc long, and the first factor, Γ1, contains all other parts of the original FST.
(C) Extraction of finite ambiguity. Factorization of a finitely ambiguous FST such that the first factor, Ψ1, is functional, i.e., unambiguous, and the second, Ψ2, retains all finite ambiguity of the original FST. Factor Ψ2 is fail-safe for any output from Ψ1, i.e., in every state of Ψ2 there is always a transition for the next symbol generated by Ψ1.
(D) Factorization of any functional FST such that the first factor, B1, is left-sequential and processes an input sequence from left to right, and the second, B2, is right-sequential and processes an intermediate sequence from right to left. B1 and B2 are jointly equivalent to a bimachine.
Each of the following processes improves one or more of the above factorizations:
(A) Reduction of the intermediate alphabet of any two FSTs that operate in a cascade. The process is applicable to the two factors resulting from any above factorization. It removes a posteriori all redundant intermediate symbols but it cannot a priori prevent their creation.
(B) Ambiguity alignment in any (at most) finitely ambiguous FST: The process deals with ε (epsilon, the empty string) on the input side of an FST. It introduces additional ε-arc to “align” a set of arcs that have all the same input symbol and the same set of alternative input prefixes. The process can be used as a preprocessing step before bimachine factorization, or before the factorization of finitely ambiguous FSTs.
(C) Reduction of the number of diacritics in the intermediate alphabet of two sequential FSTs that jointly represent a bimachine. This process is applicable in the course of bimachine factorization.
(D) “Indirect factorization” of the unknown symbol. The process is applicable in the course of bimachine factorization and of factorization of finitely ambiguous FSTs.
The foregoing factorization processes can be jointly applied to any arbitrary FST.
F. System
It will be recognized that portions of the foregoing processes (i.e., methods detaining processing instructions or operations) may be readily implemented in software as methods using software development environments that provide source code that can be used on a variety of general purpose computers. Alternatively, portions of the processes may be implemented partially or fully in hardware using standard logic circuits. Whether software or hardware is used to implement different portions of the processes varies depending on speed and efficiency requirements of the system being designed.
It will also be recognized by those skilled in the art that any resulting language processing method(s) incorporating the present invention, having computer-readable program code, may be embodied within one or more computer-usable media such as memory devices or transmitting devices, thereby making a computer program product or article of manufacture. As such, the terms “article of manufacture” and “computer program product” as used herein are intended to encompass a computer program existent (permanently, temporarily, or transitorily) on any computer-usable medium such as on any memory device or in any transmitting device.
The invention has been described with reference to a particular embodiment. Modifications and alterations will occur to others upon reading and understanding this specification taken together with the drawings. The embodiments are but examples, and various alternatives, modifications, variations or improvements may be made by those skilled in the art from this teaching which are intended to be encompassed by the following claims.
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